Heating-control appliance



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HEATING CONTROL APPLIANCE Filed July 14, 1949 5 Sheets-Sheet 1 IN V EN TOR.

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INVENTOR CHARLES C. DOYLE A EY.

Patented May 19, 1953 UNITED STATES PATENT OFFICE HEATING-CONTROL APPLIANCE Charles C. Doyle, Willoughby, Ohio Application July 14, 1949, Serial N 0. 104,720

My invention comprehends a multi-control both of the operation and/or location of a carrier for material to be heat-conditioned and of the operation and/or location of a heater. More particularly, the assembly comprises cooperative mechanisms, (1) for varying the distance between a conveying appliance and a heating appliance and doing so automatically according to whether the rate of travel of the material through the heated zone is that which attains successful results or is sub-normal, (2) for automatically varying the measure of heat to which the material may be exposed whenever the hazard of an over-exposure occurs, (3) for automatically determining both the measure of and the time for initiated heat, (4) for automatically determining the starting and ending of the relative movement between the two appliances and (5) for artificially subjecting the material to a cooling effect on emergency.

This application is a continuation in part of my application Serial No. 584,308, filed March 23, 1945, which has now been issued as Patent No. 2,479,913 of August 23, 1949.

While the particular appliance which is mounted so as to move toward or away from the other appliance may feasibly be either the conveying appliance or the heating appliance (bodily movement of a heater-adjacent part of a conveyor being old in the art and bodily movement of the heater being disclosed in my patent just identified) and similarly the character of heat generation (whether open gas flame, oven or electrical-resistance type) is variable to suit industrial conditions, I have elected to illustrate infrared, open-glow, electrical heaters and controlled bodily movements thereof because the company with which I am associated is the pio neer, both in their use and locations. An extensive series of differing applications of my heaters or dryers or conditioners progressed from the printing industry into an ever widening range of industrial uses for the processing of many materials other than printing paper and inked impressions thereon.

The multi-controls which I originated and. have successfully reduced to practice in commercial production and sales may function in different sequential order depending upon the amount of heat; the rapidity of its generation;

the character of the material to be controllably subjected to heat; its rate of travel through a heat zone; whether the heat rays'are penetrating like the infrared or directly raise the temperature by convection or through high fre- 11 Claims. (Cl. 219-19) quency currentinduction; the sensitivity of the material or some coating thereon which is to be transformed or se forv instance, printing inks; and the properties of an extensive list of patterned fabrics, synthetic products whether crystals of raw plastic or fabrications thereof.

Heating by convection, by conduction and by radiation has been practiced for years as has been the conversion of electrical energy into heat from either low or high frequency. However, a need has existed for regulatory controls which in most cases are desirably automatic in operation.

The objects of my invention are mostly declareci in the following narration which includes one complete cycle effected with the aid of specific automatic, electrically motivated controls, which are, moreover, often beneficial when the applied heat might be detrimental to adjacent objects such as machine or conveyor parts like the composition rollers on a printing press.

This disclosure pertains to the control of artificial heat for processing or conditioning many classes of material, exemplifiedly with electrically created heat and consequently by use of contactors (any kind of special-function switches) some of which are dependently subject to the actuation of what might be termed an initiating contactor. singly or in pairs, they function to control periodicity, relative location as between the heater and the material exposed to heat, amount of voltage, time of initiation of heat, time of its cessation, intensity and manner of heat transfer.

For instance, in printing a pattern on a roll of cloth it is important that the impression be quickly dried so that the material may be promptly rolled up again without smearing. As long as the material is moving past the heat source, it is safe to maintain a high temperature for transfer thereto. If the material should cease to move the material could be damaged by too long an exposure. Even when the heat is cut off there is sometimes enough residual heat to scorch or otherwise damage the material or some part of a conveyor therefor. In the presence of radiant heat, it is usually suificient merely to direct the radiation away from the material. Some mechanisms for effecting the bodily displacement either of the heater or of an adjacent part of the conveyor (roller on a printing-press feed) helpfully incorporated a counterbalance. Occasionally too, an artificial coolingmeans for some part of the conveyor may be advantageous. Since our pioneering use decades ago of the goose-neck (universal joint) support of an electric heater, we introduced: the multi-movement floor standard (Patent No. 2,455,047 of November 30, 1948); the reciprocal movement of the heater toward and away from the material, either above or below it or in both places or at one or both sides thereof, hand or power operated; one or a pair of obliquely slidable heater supports; a heater hinged at one end to a frame; a pair of heaters so turnable, like jaws, onarod which is turned by an automatically energized auxiliary motor; on a rotary press, Where little free space is provided, a number of heaters at various locations turnable around a longitudinal ,axis of each heater.

While the to and fro shift of a heater may be mechanical, pneumatic or hydraulic or electric motor actuated, in most cases the auxiliary electric motor is preferable because so readily placed in the same circuit with, say, a solenoid control of some form of .contactor likeza "'time or limit switch. I have used solenoid-s .initwo ways, one to both hold theheater in functionating position and-to moveit, theother in connection witha relay to operatethe auxiliarymotor,

a brake therefor or a. cooling agency.

A solenoid might directly actuate with itsown thrust arm with such a plunger extended while the solenoid is open or the reverse; or.-conjunctive springs might be usedeither to reverse the procedure or to furnish an addedthrust action; or compoundleverage'might constitute the solenoid actuator, either to add strength or to multiply distance; .or the energization might accomplish an arcuate motion for directly turning a heater aboutan aXis-as .bya helical inter-fitting between its actuator anda member to be turned.

Some of my heatingzunits are'equipped :witha switch control for difiering widths of wenergization according to the width of material being exposed thereto, or .the wiring zfordelivering infraredraysamay be set to .radiatelfractional heat. Likewise, the:temperature may beraisedzbyregw lating the input of electricity .by means .of .a transformer, rectifier or adjustment 'in :multip'le by means of heat-switches.

A relay switchof the magneticitypawhen energized,.serves to draw into contact;aterminalzto close an electrical circuit. For instance, :when

themain driving motor is started, a smallamount of current would .energizea magnetic 'coil which would draw two terminals into contact to complete :another electric circuit of either higher or lower voltage. In short, the circuit :forenergizing the magnetically operatedcontactor device remains quite independent thereafter of the .cir-' cult of which the terminals are a part. One-relay operates amagnetic switchto close the circuit of which my resistance heater :isa part -.and .automatically assoonas the conveyor-driving circuit is closed. Another relay operates another magneticswitchto make the connection to.start, say, an auxiliary motor "which displaces or replaces the heater. Still another relay .is introduced when a control for .a motor-brake is employed, but such relay is from :the line which :supplies current to the comparatively smalL-gear-reductionor auxiliary.motorin effect-to relay from a circuit .which'is subjectto the controlpf'a dilferent relay.

For such clarificationas it' may furnish, I add the steps of one particularcyole incommercial production:

('1) When the main motor starts, :a :small amount of current is relayedirom that motor to a magnetic switch which operates a contactor to admit current to the resistance element of the heater.

(2) Another relay from the main-driving circuit causes another magnetic switch to operate another contactor to admit current to a reversible, gear-reduction motor which actuates the energized heater or gang of heaters into a position of suitable proximity to the path of material on a conveyor which was setinoperation by the main motor.

(3) When a heater reaches its desired position, it may be stopped in its movement by a pin on a driving chain which serves to throw a limit switch to shut off current to the auxiliary motor.

-64) Thereupon a solenoid is demagnetized causing a brake, with which it is functionally associated, to snap shut and stop the auxiliary motor to maintain the heater in the position desired, as long as the entire assembly is in operation by the :main :motor.

(5) If, for any reason, the conveyor should stop moving, the procedure is reversed, initially by release "of the brake.

(6) The heater becomes deenergized.

(7) The auxiliary-motor commences-toreverse itself to-displace the heater or gang of heaters or group of appositioned heaters :between which the material may have traveled.

(8) At the proper time, a pin:in thechainreoperates a limit-switch to stop the auxiliary motor after ithas adequately displaced theheat source.

On occasion another relay effectsa contact and maintains it as long as a spring-tension of a time switch exists. This is being usedwhere proof presses are used frequently, :but only ,for short periods of time.

A further indicative of objects of .my invention to which commercial introductions by me and others havegiven rise:

Although the web of a printing press had for decades 'sagged (separated from any applied heat) whenever the press stopped, such sagging being consequent to'continued'roll movement, it later became desirable to accomplish such relative movement, as between a heater and material to be heat-processed, under control both :as to time and distance. (See,for instance, domestic patents1to'White'No.11,266,735 of 1918; ".to Barker No. 1,924,100 of 1933 and .Presby No. '2',229,0l'7 of 1941.)

A high frequency, alternating current; with an oscillator (not to be shown because .old) :as its source, is entirely feasible, subject to my rcontrolswhether suchan electricalfield communicates-heat by direct contact (when thedampened material itself may bea conductoruntil dry) .or whether by the induction method. (See patents inclass 219, sub-class 47.) .A standardwave length may be adopted and be variable withthe voltage.

11 also contemplate occasional employment of a transformation of a low voltage into a high amperage, suitable resistance elements being caused successively to receive current subject to one of my control combinations.

Selectorsas control adjuncts for permitting energization of auxiliary circuits may be either manual, clock-mechanism governed to establish a predetermined time interval or may be automatically operative whether thermostatically or magnetically controlled, will be regularly incorporated to satisfy specific requirements.

n cooling agency, illustrated to supply, say,

refrigerated air to a roller or other surface in proximity to which the earlier heated material is to pass, will at times be desirable (for instance, when printing gummed tape so as not to wind a heated roll) along with conduits, sometimes, for recovering the cooling medium preparatory to redistribution.

So too, while the pre-heating of the paper on a printing press (1. e. before printing thereon) has earlier been adopted, being highly desirable as an avoidance of a, delay even for a few minutes when a special newspaper edition is to be run, my controls accomplish preheating automatically by effecting a pre-energization of the heater and to any chosen degree of temperature along any required spatial area. Gangs of heaters arranged in a row, longitudinally along the path of travel of the material may be variously controlled--either by terminating heat-delivery by any preferred group of the heaters, by varying the amount of heat from some or all through an automatically operated rheostat subject to the stoppage of sub-normal rate of travel of the material.

Advertising to the drawing:

Figure 1 is a diagrammatic elevation of a conveyor comprising winding and unwinding rolls and embodying my inventions with certain parts shown by dot and dash lines in alternative positions. (This figure is a duplicate of Fig. 1 of the parent case.)

Figure 2 is a wiring diagram including one marketed type of delayed-action switch whereby the heater becomes energized an interval of time after the machine on which it is mounted has commenced operation. (This being a duplicate of parent Fig. 3.)

Fig. 3 is a Wiring diagram of Figure 2 comprising an automatic relay contactor.

Figure 4 is a high-frequency, alternating-current electric-heater modification comprising the dielectric principle using two plates between which the material travels.

Figure 5 is another high-frequency modification showing the contactual, resistance principle of heat-exchange by direct contact with the material.

Figure 6 is a further high-frequency heatlug-appliance modification, illustrating theinduction principle.

Figure '7 is a wiring diagram comprising a timeswitch and transformer for selective attainment of high-amperage from low voltage.

Figure 8 is a wiring diagram comprising a selector-contactor which besides being automatic might be manual, clock-mechanism actuated, or thermally controlled in actuation, whereby, for instance a pro-heating might be effected.

Figure 9 shows in conjunction with means for swinging heating units away from an appositioned position to the path of a web of materiala cooling agency for the material subsequent to its heat-conditioning, exemplified as a water- 'cooling roll.

Figure 10 is a more elaborate wiring diagram for performing theeight steps of the particular cycle earlier described in this specification.

Figure 11 is a modified diagram comprising a fluid-pressure actuating mechanism.

It is to be understood that some form of relay or automatic contactor-control will be employed except in the simpler installations, consequently, that, for instance, in combination with the showings of Figures 4, 5, 6 and 9 some appropriately selected control appliance is to be considered as contemplated to be cooperatively included in said four figures of the drawings even though not superfluously reillustrated therein because no claim of novelty is made for units of th electrical hook-ups by themselves, instead only for some automatic control (spacing between heater and material, timing of initiation of material travel or of heater energization or thermal) of the distinct assemblies.

The illustration of the winding and unwinding rolls in Figure 1 were selectedto simplify. Essential here is that some form of heater be appositional, below, above from either side or both above and below or from both sides of traveling material which the first figure merely exemplifies as being the web of a printing press. The desirable use of some species of control comprehended by my inventions, having priority to early 1944, whereby(a) a deenergization of the heater occurs when the travel of material past it ceases or is at a sub-normal rate of speed, (1)) separation of the path of material and source of heat as an added safeguard when an excess of residual heat obtains, (c) delayed action of heat delivery, (cl) preheating is occasionally required, (e) high-frequency current as the source of heat to be transferred, (1) voltage-toamperage control, (g) subsequent cooling (refrigerated air in lieu of water), (h) control of the start of material and heater separation or of restoration of their effective proximity or control of the cessation of either, (i) having one automatic control subject in its operation to another contactor control as conditions may determine to be expedient.

Spaced pedestals l and 2 respectively constitute a support for carrying shafts 3 and 4 on which indeterminately long lengths of, say, printing paper, wall paper or textile material are to be rolled and unrolled with an intermediary web to be exposed to artificial heat. The rolled paper on the shaft 3 has been designated by the numeral 5, that on the shaft 4 with the numeral 6 and the web with the numeral '1. Pivotally mounted on a fixture or part of the press at 8 and intermediately of its ends is a bracket 9 to which is attached the open side of an electrical (radiant) heater iii. Another fixture carries a conventional socket terminal H for the reception, in one position of the heater, (here exemplified as the displaceable unit for varying the distance between it and the material being processed) of a dual-prongplug l2 which is attached to the upper side of the free end of the bracket 9 and from which it is insulated. A counterweight i3 has a bowed connection with the bracket 9 on the opposite side of the pivot 8 to serve the ordinary purpose of insuring a smoother, downwardly-swinging displacement of the heater, yet subject to the dampening function of a device comprising a rod l4 having one end turnably connected with the heater casing, its other end articulated at 5 with one end of another rod it while its other end is operatively connected with a frictional check or movementrestraining contrivance H. The other pedestal 2 has a pivot 68 for a lever l9 to be considered as the manual control for press operation. W hatever the mechanical connection with the upper end of the lever is, its other or lower end is adapted to rock, about a pivot point 2i], an elongated extension 2! terminating as a flat finger 22 whichmay be caused to underlie a suitable projection 8a on the bracket 9. When in that position .it serves to maintain the plug [2 within the socket H against the tendency of the-counterweight 13 to eilectza withdrawal of the former fromthe latter. An actuation .of the press-control-lever to stop the press, will swing the extension 2! downwardly to its dot-and-dash-line position, shown, whereby presently to permitthe projection-8a to swing clear of the extremity of the finger 22 in response :to the action of the counterweight l3 untilthe heater and counterweight ultirnately assume their dot-and-tdashline positions. Now evident should .be that any stoppage of the press will break the electrical connection at li--l2 for supplying current to the heater l5 and also cause the bodily swing of the heaterso that its residual heat is removed to a zone more remote from the. path of travel ofthe material. In this form of my invention the-heater is to be manually restored to its functioning position and there maintained upon operation, of the press pecause'the press-drivmgmotor, electro-magnetic means and heater are in thesame circuit.

The wiring diagram of Figure 2 comprises an electric motor 3A, a switch 32 forsimultaneously closing both the press operation or conveyor and heater 33 circuit. However, included is 'atirne relay 3 which has a delayed action in "its control of the closing of the auxiliary circuit. Such relays are adjustable as to time-range. 'A fraction'of a minute has served my purpose of delaying heater-energization until the inaterialapproaches a normal rate of-speed and of-also making the drag of heater energizaticn successive to press operation.

Since all of the illustrated applications of my inventions'are to comprise at least one controlcontactor or an equivalent relay or predeterminedly operable switch, in combination with a primary electric circuit and with one or moreauxiliary circuits and with an electric motor (or electrically-controlled driving means) and-with a heater (not necessarily electrically generated), it has been judged unnecessary to illustrate every unit (old by itself) in every combination which has been selected for exemplifying portrayal in the drawings. In some figures i, 5, 6 and 7) the material-conveyor has been omitted, in Figures 3, 8 and 10 the stock to be heat-processed and mechanism formoving it in proximity to the heaters shown in Figures 3 and 8, while in Figure 10 even omitted is the heater to be reciprocably swung by the auxiliary motor with its magnetic brake.

The diagram of Figure 3 includes amachine and/ or conveyor-operatin motor'35 and-a heater 36. Three lines 3'7, 38-and-38 ailord efiective electrical connection between the motor 35 and the heatertS in combination with an automatic relay 40 (which may be any one of several market-approved type), whereby there 'is a dependence of energization of the auxiliary heater 38 circuit by pre-set delay even after the closing of the primary circuit for starting the motor and a conveyor (not shown) for any material to be heat or dry processed.

Figure 4 is one high-frequency current application showing a sheet of material 4i traveling between a pair of dielectric plates 42 and 43 having leads t4 and 4-5 respectively.

Figure 5 is another form of high-frequency adaptation wherein the material 46 to be conditioned is subjected to high-frequency-generated heat byrods 27 and it having leads wands-5c respectively. This type of application supplies 'contactual resistanceheatingof the material 16,

.a principle :ol'dby itself, yet considered to be .patentablynew subject to any 'one v 0f my oom tactor controls elsewhere herein shownand described.

:Figure 6 illustrates adequately, .I believe, the induction principle .of high-frequency heatingthe material 5i passing, as exemplified, through aicoiled. loop 52.

It is to be observed in .each'oi Figures 4, 5 and 6 that .a passageway is provided through which theimaterial to the heat conditioned will travel, likewise. during the-coacting control of the heater by at least one relay.

Figure 7 a- .supposedly-requisite partial wiring :diagram, in view of earlier explanations, lacking'thetraveling material and the controlled heater :unit. A tube control-circuit, three-phase motor and a voltage regulator including a variable transformerare-comprehended. Any-standard, "marketed automatic 'voltage regulator may be used. .A 230 volt line 53, a. 115 volt line 54 supply constant output at 55 through the agency :of the coil 56. Any commercially approved time-switch 57 is advantageously.incorporated.

Figure 8 illustrates a wiring diagram for a main motor 58,-heater 59,,source-lines 66,451 and 62, automatically operative contactor 63, which latter maybe clock timecl, or a time-relay or a thermal switch; a manually operable selector switch and a magnetic switchlifi. The foregoinghas beendemonstrated to be not only a feasible, but advantageous hook-up for accomplishing a ure-heating.

The contractor .63 may be set to energize the heater 59 a predetermined time before the motor 53 is energized, but will, after an interval, deenergize the heater SB. Alternatively, thetimer 63 may regulate the temperature of? the heater 58 on a percentage basis, for instance, at ninety per cent the energization is in cycles of on ninety percentof the timeand oil ten percent of the time. The hook-up would be. in the. nature of a. reversal asto sequence of operation as compared with the function ascribed to therelay inFigure-Z. The selector switch'65 may be athreeposition switch for efiecting an automatic eneremotion of the heater-59 by closure at 65 to ef- 'fect closure ch66 whenthe motor 58 is'operating or alternatively the selector $5 may b manually operated to energize the heater after the magnetic-switch d; is-closed when the motor 58 is not being driven, or to disengage the coil cf the automatic relaycompletely sothat the heater 'will not become energized regardless of whether the motor 58 is or is not operating. The relay symbol shown in dash-lines is to represent any one of the following:

(1) A. thermal switch for controllin the initiation of energization of the heater whenthe material attains its proper temperature.

(2) A clock timer or time-relay so that the 'energization of the heater may becontrolled (established) for a predetermined time orfto become energized subsequently if desired.

(3) The variable contactor63 might, indeed, be incorporated on either or both sides of the two lines coming from the motor switch-depending upon the heating time-differential pre-setting which conditions may make'desirable.

In Figure .9 is; the introduction 'of a thermal control, asexemplified, a cooling agency operabl upon the traveling material subsequent to its heating orsdrying. .An unwinding roll 61, say, for a web of printing paper 68, travels in suitable proximity across a pair of my infrared heaters 69 when the latter are in their functioning position, as shown. However, the heaters 69 are bodily displaceable (downwardly in this instance) by an auxiliary electric motor ill operating through a train of gears (not shown, because not claimed specifically) to swing the heaters about a pivot point H on a frame 12. After conditioning, the material 68 travels in contact with a water-coolin roller 13 which is held at an adequately lower temperature by a refrigerant, instanced as chilled water circulated through the roller 13 by means of a conduit system including a, pipe 14.

In Figure there is disclosed a wiring diagram for a multiple contactor-control system of a primary electric circuit together with a plurality of auxiliary electric circuits. Essential to designate are a main motor 18 which when started admits current by relay to a magnetic switch 19 which operates a contactor permitting current flow to the heater motor 8!. Another relay 80 causes another magnetic switch to operate another contactor to admit current to a reversible, gearreduction motor 8| equipped with a magnetic brake 82, both of which may be of standard commercial design. The auxiliary motor 8| will shift the position of a heater or heaters (not shown) in a manner similar to the showing of Figure 9. When the heater reaches either limit of its swinging movement it is automatically stopped, say by a forward-limit switch 83 and again by a reverse-limit switch 84. A solenoid-operated and automatically-operated brake 82 associated with the motor 8! serves to stop the actuation of the latter more promptly in timed relation. Magnetic reversing switches 85 functionall in a manner old and well known in the specialised art. Manifestly, should the main-motor driven conveyor chance to stop while the heater or gang of heaters are in proximity to the path of travel of material carried by the conveyor, with hazard of injury to the material from over-heating, the cycle becomes reversed, initially by release of the brake 82, and by deenergization of the heater or group of appositioned heaters as shown in Figure 1.

The main contactor 19 (with relay switch) shown as a front view in Figure 10, and has been of a type having two circuit controls which are alternately open and closed according to whether the exemplifying press is stationary or in operation. When it conveys electric current or is on it serves to elfect contact on the forward side of the magnetic controller 85 which exercises the function of reversely actuating the heating assembly into serviceable position. The front view of the magnetic reversing switch 85, for instance, a type having only one half magnetized, may make a connection to drive the reversible motor BI and move the heater forwardly into suitable proximity to the path of travel of the sheet material. When the sheet-conveyor stops, the switch 19 becomes deenergized yet relays magnetic power to the other half of the reversing switch 85. However, because the small heater-actuating motor 8| would be turning "forward as long as the material-conveying mechanism is running or would be turning backward continuously after the conveyor stopped, it is desirable to employ limit switches 33 and 84, both of the long publicly used lever type and having top views illustrated. They break the connection after the motor 8| has adequately advanced or retracted the heater, subject to the motor l8 and relay 19 i. e. energization or deenergization therethrough. After the heater has traveled forward into properly effective position, a trigger presses down a switch lever to break connection and to stop forward movement throughout the duration of conveyor movement. The reverse occurs after the heater has become adequately displaced. Thus the forward limit switch 83 and the reverse limit switch 84 control their respective contacts in the magnetic reversing or motor 8| controller switch 85, alternately to open and to close according to whether power at the relay switch 19 is on or off. The switch 85, when closed, reverses the motor 8!. When the relay 19 relays forward it magnetizes on half of the switch 85 to drive the motor 8| so as to advance the heater toward the path of the material. Finally, the motor brake 82 has been one of the extensively used, or standard types here employed to hold the heater assembly in either extreme position, and operable by a magnet energized while the heater-motor BI is running to release the braking action against spring pressure or vice versa.

The essentials of this invention are a heater adjacent to the path of movement of material to become exposed to its heat, however generated, and. a series of electrical controls comprising the use, in auxiliary circuits, of varying types of contactors i. e. switches, relays or other electrical circuit make and break units) so coordinated in exercise of function as to achieve cooperation in attainment of results which are best suited to the material, with or without coating thereon, which is to be conditioned by the controlled application of heat. One of the contactors is arranged so as to be adapted to control the initiation of operation of some kind of auxiliary motivator for periodically regulating the distance between the path of the material and the source of heat while that particular contactor is subject in its actions to one or more other contactors.

In Figure 11, a primary motor 85 effects the travel of the material by driving such mechanism as best serves. Many kinds of conveying mechanisms have long, been used in many industrial fields, wherefore here chosen has been only enough for driving the pair of standard rolls for directly causing travel of a web which exemplified in the parent application of 1945. The electric motor 86 has a driving connection 81 with an impression cylinder 88 between which and a printing cylinder 89 the web 90 is frictionally advanced from a feed roll 9| to a rewind roll 92, as indicated by the arrows. A switch 93, connected with the power lines 94, functions to energize or deenergize the motor 86. The switch 93 may be either manually or automatically operable. Current is led to a relay 95 which controls a selector switch 96, shown to be also connected with the power lines 94, and adapted to supply current to, or cut it off from, the leads 9'! of an auxiliary circuit and thence to the resistance unit or units of an electric heater 98. Leads 99, energized from the switch 93 when closed, connect with a second relay I00 adapted to form part of another auxiliary circuit intended, as exemplified, to motivate the heater 98 bodily, but subject to the control here of a bimetallic thermostat it! which is located in proximity to the path of travel of the material 90. The relay I00 and thermostat ltl coact to control the operation of a solenoid I02 and it in turn controls the operation of a fourway, fluid-pressure valve I03 which is connected in a feasible manner with inlet, and outlet. tubes both of which arenumbered l; because direc tion arrows identify them. The tubes lead to which from opposite ends of'a cylinder its within which there is a piston lflfiwhich hasconnection, by means of a rod 591 with theheater 93; Further details are unneeded because such a structure is old,,used: in many arts and is not specifically claimed. The modified showing isintended to portray anequivalent, fluid-pressure motivator in substitution, for the auxiliary motor or 3% of other figures. As will be readily understood, in operation the ascent and descent of the heater 98 will be according as the thermostat 1 ti attains a hazard-temperature, which means above the desired maximum, or not, respectively while subjectto the-control of the solenoid iE- Z and valve H33,

I claim:

1. An electric h ating-control. appliance comprising the combination of a frame, an electrically driven conveyor mounted for movement on said frame, an electric heater movably mounted on said frame for adjustable locationrelative to said conveyor, a brake-equipped electric motor arranged to actuate said heater mounting and a pair of automatically operative contactor means in an auxiliary electrical circuit together with said motor for alternately energizing it and its brake whereby automatically to shift the location of said heater.

2. In an electric control appliance, the combination of a frame, an electric motor, a conveyor for sheet material to be heat conditioned and movably mountedon said frame, a switch to control conveyor operation, an electric heater movably connected with said-frame and adapte for bodily displacement as a. unit and appositionable to said conveyor, a time switch, contacts operated by said time switch and included, in an electrical circuit which includes said heater for controlling energization of said motor and for establishing a presetting for a predetermined period of time of pre-heating: by said heater until said motor is energized by. time-switch closure of the entire circuit and a contactor device in. a circuit with said heater and responsive to the displacement movement of said heater.

3. The combination for use with a carrier'for material, of electrically operable mechanism including an electric motor arranged to actuate such a carrier, an electric heater. supportedin apposition to thepa-th of movement of the ma terial and connected in a circuit to become energized together with said motor, a motivator for causing relative movement to be imparted between the material carrier and heater and an electrical control appliance arranged in a make and break circuit with said motor and motivator and including: a contactor for governing-the operation of said motivator, an electrical instrument for predeterminedly establishing a timedifferential of material-carrier operation and of heater energization and a second. contaotor subject in its operation to the functioning of said instrument for effecting in predetermined order of time the operation ofrsaidv mechanism and of said motivator.

4. The combination as in claim 3 wherein thin, coated material is exposed to an infrared-ray heater achieving penetration both of the material and of the coating thereon, therelay isa thermostatic switch subject to the: temperature of the heater and the time-differential'is of heater energization whereby to permit selectable preheating prior to the operation of the motor for said carrier.

5. An electric heating-control appliance com.- prising the combination of a frame, an electrically driven conveyor mounted for movement on said frame, an electric heater movably connected adjacent to said conveyor for adjustablepositioning relative to the latter, said conveyor and heater being connectable in a primary electrical circuit, a motivator arranged to actuate said heater and a pair of automatically operablecontactors in an auxiliary electrical circuit, one of said contactors having a predeterminably-responsive control of the energization and deenergization of said auxiliary circuit'and the other one of said contactorsbeing subject in operation to said first mentioned contactor and arranged to control the operation of said motivator automatically to shift the, position of said heater in responseto operation of said electrically driven conveyor.

6. In an electrical heating-control appliance, the combination ofv a frame, electrically operable mechanism for feedingmaterial to be conditioned across said frame, an electric heater carried. by said frame adjacent to the path to be traveled by the material, reversible mechanism for effecting relative movement between said material-feeding mechanism and heater by bodily. displacement of one toward and away from the'other, electrical connectionsfor causing one of said mechanisms and said heater to become energized and deenergized, said connections including relay controls each including contacts operated thereby respectively. and arranged for hook-up in an electrical circuit which includes said heater, one of said relay-controls being; arranged and adapted to govern the operation of one of said mechanisms, oneof sa-id-relay-controls beingsubjeot in itsoperation to the other whereby the relative-movement-effecting mechanism is permitted to operatein a predetermined time relationship according to the setting established for the other, initiating relay-control and an auxiliary circuit including connectionswith said subjectrelay control and arranged, when energized, to effect the reversal of said lastmentioned mechanism.-

7. In combination, a frame, an electric motor, a conveyorand an electric heater, said conveyor being mechanically and said heater being, electrically connected with said motor foroperation and energization respectively of the conveyor and heater, an adjustable mounting between said frame and heater, an auxiliary motivator for actuating said heater mounting, apair of electrical control devices including one provided with contacts arranged for time-interval make and break operation and theother subject in its operation thereto and arranged for energization or deenergization whereby to govern the starting and stopping of said auxiliary motivator, connections forming a pair of electrical circuits of which said control devices are parts respectively and said connections including a contactor for controlling the flow of current through said last mentioned pair of circuits respectively and in relatively timed relation.

8; In an electrically operable assembly of the kind described, the combination of a frame, an appliance including an electric motor for conveying material to be heat-conditioned and mounted on said frame, an electric-heating appliance, one of saidappliances being adjustably mounted on said frame, electrical connections including a relay. between said appliances whereby movement of the conveying appliance, consequent to its motor being in a common circuit, energizes said heating appliance, a switch for open ing and closing said circuit, another electrical circuit arranged to receive voltage from said first mentioned circuit, other electrical connections comprising an independently powered motivator for effecting relative movement between said appliances and also comprising a switch for opening and closing said last mentioned circuit and further comprising automatically operative, electromagnetic means responsive in operation to the first mentioned switch for actuating said last mentioned switch to control operation of said motivator whereby to vary the distance: between the path of travel of the material on said conveying appliance and the heated zone of said heating appliance as occasion may require.

9. In an electric-control appliance, the combination of a frame, a conveyor mounted for movement thereon, a motor in a primary circuit for actuating said conveyor, an electric heater in an auxiliary circuit and supported on said frame for apposition to the path of movement of said conveyor, a motivator for effecting relative movement between said conveyor and heater bodily, an electrical connection including a switch for starting and stopping said motor and controlling the primary circuit, a relay arranged to operate in response to the condition of said conveyor for controlling said auxiliary circuit, a contactor controlling such auxiliary circuit, said contactor being subject to the energization of the primary circuit through said relay, a second relay selectively arranged to be alternatively responsive to electrical impulse according to existence of a closed circuit of said switch and contactor, a second contactor subject in operation to said last mentioned relay, a second auxiliary circuit energized or deenergized by said last mentioned contactor, said second auxiliary circuit including an electrical control device and said motivator being governed thereby, whereby the power of said motivator is initiated to effect the relative movement between the conveyor and the heater.

10. The combination as in claim 9, wherein there are heater sections in switch-separable circuits and also additional relays connected with the conveyor motor, said additional relays being arranged to break the circuits to fractional parts of the heater in accordance with the speed-setting of the conveyor motor, whereby at one specific rate of conveyor speed a suitable fraction of the heater divisions become energized.

11. In combination, a support, mechanism for effecting the travel of material to be heat-conditioned and operatively mounted on said support,

an electric motor arranged to drive said mechanism, an electric heater supported in apposition to the path of travel of material and arranged for connection in a primary circuit along with said motor, an auxiliary circuit including a contactor for controlling the effective application of heat from said heater, the alternative operations of said contactor being subject to variant conditions of being of said mechanism, a second auxiliary circuit including a motivating appliance and a switch-control, the latter responsive to the positions assumable by said contactor, the alternative positions of said switch being determinative the quiescence and operation respectively of said motivating appliance whereby automatically to establish an interdependent double control by flow of current through said auxiliary circuits in selectably timed relation.

CHARLES C. DOYLE.

References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,266,735 White May 21, 1918 1,308,380 Tweedy July 1, 1919 1,366,069 Doyle Jan. 18, 1921 1,450,022 Doyle Mar. 27, 1923 1,468,289 Eschenbach Sept. 18, 1923 1,479,819 Kluever Jan. 8, 1924 1,555,860 Ledwinka Oct. 6, 1925 1,646,498 Seede Oct. 25, 1927 1,880,114 Smith Sept. 27, 1932 1,924,100 Barker Aug. 29, 1933 1,955,055 Date Apr. 17, 1934 1,969,666 Avery Aug. 7, 1934 2,079,708 Hart, Jr May 11, 1937 2,113,770 Richardson Apr. 12, 1938 2,127,956 Helmer Aug. 23, 1938 2,177,299 Fredrickson Oct. 24, 1939 2,204,801 Gessler June 18, 1940 2,227,174 Baster Dec. 31, 1940 2,229,017 Presley June 14, 1941 2,268,986 Hess Jan. 6, 1942 2,325,950 Greene et al Aug. 3, 1943 2,381,274 Frostick et a1 Aug. 7, 1945 2,420,399 New May 13, 1947 2,448,009 Baker Aug. 31, 1948 2,448,011 Baker et al Aug. 31, 1948 2,455,047 Doyle Nov. 30, 1948 2,479,913 Doyle Aug. 23, 1949 2,541,416 Harrison Feb. 13, 1951 FOREIGN PATENTS Number Country Date 340,057 Great Britain Dec. 24, 1930 

